73116-18-4Relevant academic research and scientific papers
Efficient, stereodivergent access to 3-piperidinols by traceless P(OEt)3 cyclodehydration
Huy, Peter H.,Koskinen, Ari M. P.
, p. 5178 - 5181 (2013)
A stereodivergent and highly diastereoselective (dr up to >19:1 for both isomers), step economic (5-6 steps), and scalable synthesis (up to 14 g) of cis- and trans-2-substituted 3-piperidinols, the core motif of numerous bioactive compounds, providing efficient access to the NK-1 inhibitor L-733,060 is presented. Additionally, a "traceless" (referring to the simplified byproduct separation) cyclodehydration realizing simple P(OEt)3 as a substitute for PPh3 is developed.
Controlling Plasma Stability of Hydroxamic Acids: A MedChem Toolbox
Hermant, Paul,Bosc, Damien,Piveteau, Catherine,Gealageas, Ronan,Lam, Baovy,Ronco, Cyril,Roignant, Matthieu,Tolojanahary, Hasina,Jean, Ludovic,Renard, Pierre-Yves,Lemdani, Mohamed,Bourotte, Marilyne,Herledan, Adrien,Bedart, Corentin,Biela, Alexandre,Leroux, Florence,Deprez, Benoit,Deprez-Poulain, Rebecca
supporting information, p. 9067 - 9089 (2017/11/14)
Hydroxamic acids are outstanding zinc chelating groups that can be used to design potent and selective metalloenzyme inhibitors in various therapeutic areas. Some hydroxamic acids display a high plasma clearance resulting in poor in vivo activity, though they may be very potent compounds in vitro. We designed a 57-member library of hydroxamic acids to explore the structure-plasma stability relationships in these series and to identify which enzyme(s) and which pharmacophores are critical for plasma stability. Arylesterases and carboxylesterases were identified as the main metabolic enzymes for hydroxamic acids. Finally, we suggest structural features to be introduced or removed to improve stability. This work thus provides the first medicinal chemistry toolbox (experimental procedures and structural guidance) to assess and control the plasma stability of hydroxamic acids and realize their full potential as in vivo pharmacological probes and therapeutic agents. This study is particularly relevant to preclinical development as it allows obtaining compounds equally stable in human and rodent models.
α-ALKYLATION OF ACYCLIC AMINO ACIDS WITH SELF-REPRODUCTION OF THE CENTER OF CHIRALITY. A NEW ROUTE TO (S)-(+)-α-ALKYLATED ASPARTIC ACIDS.
Fadel, Antoine,Salaun, Jacques
, p. 2243 - 2246 (2007/10/02)
The amino acids 1a-d (alanine, phenylalanine, valine and methionine) are alkylated by ethyl bromoacetate, with inversion of configuration, to provide readily with high stereoselectivity the α-alkylated aspartic acids 9a-d through the chiral enolates 7a-d
